Accelerated cyclic oxidation testing protocols for thermal barrier coatings and alumina‐forming alloys and coatings

Stiger, M. J.; Meier, G. H.; Pettit, F. S.; Qian, Ma; Beuth, Jack; Lance, Michael J.

doi:10.1002/maco.200503896

Cited by 8 publications

(1 citation statement)

References 16 publications

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“…Interfacial toughness plot is used to indicate the loss of coating adhesion with exposure to high temperatures [76]. M. J. Stinger et al tried to measure the adherence of the coating with finite element simulation and the indentation is employed to measure toughness along TGO thickness and stress [77].…”

Section: Spallation Failurementioning

confidence: 99%

Numerical simulation of a load-based microindentation technique for nde on thermal barrier coating systems

Lee¹

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The durability and life-cycle of thermal barrier coatings (TBC) applied to gas turbine blades and combustor components limits the maximum temperature and subsequent efficiency at which gas turbine engines operate. The development of new materials, coating technologies and evaluation techniques is required if enhanced efficiency is to be achieved. Of the current ceramic materials used in turbines, Yttria stabilized zirconia (YSZ) is widely used for TBCs are most prevalent, due to its low thermal conductivity, high thermal expansion coefficient and superior mechanical strength. However, thermally grown oxide (TGO) and thermal expansion coefficient mismatch are the major causes of large residual stress and will cause interfacial rumpling instability leading to large scale spallation failure. Through finite element simulations, it is shown that the residual stresses generated within the thermally grown oxide (TGO), bond coat (BC), YSZ and their interfaces create slight variations in indentation unloading surface stiffness response prior to spallation failure. In this research, a load-based micro-indentation method for NDE of TBCs exposed to thermal loads is investigated. The surface stiffness response is measured to assess damage accumulation and identify macroscopic debonding failure sites. Finite element analyses indicate that high YSZ/BC interfacial rumpling leads to the development of both in-plane and out-of-plane residual stresses upon cooling. Additional rumpling of this interface as a result of non-uniform TGO growth leads to enhanced residual stresses. Finite element analyses of YSZ/TGO/BC interfacial stresses generated upon cooling provide an explanation for the experimentally observed micro-cracking and failure patterns. The associated coating degradation is evaluated using a non-destructive load based multiple partial unloading micro-indentation procedure. The results show that the proposed micro-indentation evaluation technique can be an effective and specimen independent TBC-failure-prediction tool capable of determining the location of initial spallation failure prior to its actual occurrence.

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Section: Spallation Failurementioning

confidence: 99%

Numerical simulation of a load-based microindentation technique for nde on thermal barrier coating systems

Lee¹

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Evaluation of High-Temperature Oxidation Behavior of Inconel 600 and Hastelloy C-22

Hashim¹,

Hammood

Hammadi³

2015

Arab J Sci Eng

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Development of High-Entropy Alloys as Bond Coats: A Thermodynamic and Kinetic Perspective

Anupam,

Guruvidyathri,

Vaidya

2023

Trans Indian Natl. Acad. Eng.

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Accelerated cyclic oxidation testing protocols for thermal barrier coatings and alumina‐forming alloys and coatings

Cited by 8 publications

References 16 publications

Numerical simulation of a load-based microindentation technique for nde on thermal barrier coating systems

Numerical simulation of a load-based microindentation technique for nde on thermal barrier coating systems

Evaluation of High-Temperature Oxidation Behavior of Inconel 600 and Hastelloy C-22

Development of High-Entropy Alloys as Bond Coats: A Thermodynamic and Kinetic Perspective

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